Renesas
Support Isochronous transfer additionally
Dependents: USBHostC270_example_GR-PEACH USBHostDac_example USBHostDac_Audio_in_out
Fork of
USBHost_custom
by 
Renesas
USBisochronous/USBIsochronous.cpp
- Committer:
- HinoNaka
- Date:
- 2017-04-21
- Revision:
- 41:5c3ebf7372ee
File content as of revision 41:5c3ebf7372ee:
// USBIsochronous.cpp
#include "USBHostConf.h"
#include "USBHost.h"
#include "USBIsochronous.h"
#if defined(TARGET_RZ_A1H)
#include "ohci_wrapp_RZ_A1.h"
#endif
#define OR_CONTROL_PLE 0x00000004
#define OR_CONTROL_IE 0x00000008
//#define ISO_DEBUG 1
#ifdef ISO_DEBUG
#define ISO_DBG(x, ...) std::printf("[%s:%d]"x"\r\n", __PRETTY_FUNCTION__, __LINE__, ##__VA_ARGS__);
#else
#define ISO_DBG(...) while(0);
#endif
#define TEST_ASSERT(A) while(!(A)){fprintf(stderr,"\n\n%s@%d %s ASSERT!\n\n",__PRETTY_FUNCTION__,__LINE__,#A);exit(1);};
HCITD::HCITD(IsochronousEp* obj, uint16_t FrameNumber, int FrameCount, uint16_t PacketSize) {
Control = 0xe0000000 | // CC ConditionCode NOT ACCESSED
((FrameCount-1) << 24)| // FC FrameCount
TD_DELAY_INT(0) | // DI DelayInterrupt
FrameNumber; // SF StartingFrame
BufferPage0 = const_cast<uint8_t*>(buf);
BufferEnd = const_cast<uint8_t*>(buf) + PacketSize * FrameCount - 1;
Next = NULL;
ep = obj;
uint32_t addr = reinterpret_cast<uint32_t>(buf);
for(int i = 0; i < FrameCount; i++) {
uint16_t offset = addr & 0x0fff;
if ((addr&0xfffff000) == (reinterpret_cast<uint32_t>(BufferEnd)&0xfffff000)) {
offset |= 0x1000;
}
OffsetPSW[i] = 0xe000|offset;
addr += PacketSize;
}
}
void IsochronousEp::init(int addr, uint8_t ep, uint16_t size, uint8_t frameCount, uint8_t queueLimit) {
//ISO_DBG("%p FA:%d EP:%02X MPS:%d\n", this, addr, ep, size);
TEST_ASSERT(addr >= 1);
TEST_ASSERT(size >= 8 && size <= 1023);
m_pED = new _HCED(addr, ep, size);
TEST_ASSERT(m_pED);
m_pED->setFormat(); // F Format ITD
m_PacketSize = size;
TEST_ASSERT(frameCount >= 1 && frameCount <= 8);
m_FrameCount = frameCount;
TEST_ASSERT(queueLimit >= 1 && queueLimit <= HCITD_QUEUE_SIZE);
m_itd_queue_limit = queueLimit;
m_itd_queue_count = 0;
reset();
HCITD* itd = new_HCITD(this);
m_pED->init_queue<HCITD>(itd);
TEST_ASSERT(itd);
if (itd == NULL) {
return;
}
#if defined(TARGET_LPC1768)
_HCCA* hcca = reinterpret_cast<_HCCA*>(LPC_USB->HcHCCA);
#elif defined(TARGET_RZ_A1H)
_HCCA* hcca = reinterpret_cast<_HCCA*>(ohciwrapp_reg_r(OHCI_REG_HCCA));
#endif
TEST_ASSERT(hcca);
if (hcca == NULL) {
return;
}
hcca->enqueue(m_pED);
}
void IsochronousEp::reset(int delay_ms)
{
#if defined(TARGET_LPC1768)
m_FrameNumber = LPC_USB->HcFmNumber + delay_ms;
#elif defined(TARGET_RZ_A1H)
m_FrameNumber = ohciwrapp_reg_r(OHCI_REG_FMNUMBER) + delay_ms;
#endif
}
HCITD* IsochronousEp::new_HCITD(IsochronousEp* obj) {
HCITD* itd = new(m_PacketSize*m_FrameCount)HCITD(obj, 0, m_FrameCount, m_PacketSize);
if (itd == NULL) {
return NULL;
}
return itd;
}
HCITD* IsochronousEp::isochronousReceive(int timeout_ms) {
TEST_ASSERT(m_itd_queue_count >= 0);
while(m_itd_queue_count < m_itd_queue_limit) {
if (m_pED == NULL) {
ISO_DBG("m_pED is NULL");
break;
}
if (m_pED->Skip()) {
break;
}
HCITD* blank_itd = new_HCITD(this);
((HCITD *)m_pED->TailTd)->SetStartingFrame(m_FrameNumber);
m_FrameNumber += m_FrameCount;
TEST_ASSERT(blank_itd);
if (m_pED->enqueue<HCITD>(blank_itd)) {
m_itd_queue_count++;
}
enable(); // Enable Periodic
}
HCITD* itd = get_queue_HCITD(timeout_ms);
if (itd) {
m_itd_queue_count--;
}
return itd;
}
int IsochronousEp::isochronousSend(uint8_t* buf, int len, int timeout_ms) {
//ISO_DBG("buf: %p, len: %d", buf, len);
HCITD* itd;
if (m_itd_queue_count >= m_itd_queue_limit) {
itd = get_queue_HCITD(timeout_ms);
} else {
itd = get_queue_HCITD(0);
}
if (itd) {
delete itd;
m_itd_queue_count--;
TEST_ASSERT(m_itd_queue_count >= 0);
}
TEST_ASSERT(m_itd_queue_count >= 0);
if(m_itd_queue_count < m_itd_queue_limit) {
if (m_pED == NULL) {
ISO_DBG("m_pED is NULL");
return 0;
}
if (m_pED->Skip()) {
return 0;
}
itd = new_HCITD(this);
TEST_ASSERT(itd);
//ISO_DBG("m_pED: %p itd: %p", m_pED, itd);
((HCITD *)m_pED->TailTd)->SetStartingFrame(m_FrameNumber);
m_FrameNumber += m_FrameCount;
memcpy(const_cast<uint8_t*>(((HCITD *)m_pED->TailTd)->buf), buf, len);
if (m_pED->enqueue<HCITD>(itd)) {
m_itd_queue_count++;
}
enable(); // Enable Periodic
//ISO_DBG("m_itd_queue_count: %d", m_itd_queue_count);
return len;
}
return 0;
}
HCITD* IsochronousEp::get_queue_HCITD(int timeout_ms) {
osEvent evt = m_queue.get(timeout_ms);
if (evt.status == osEventMessage) {
HCITD* itd = reinterpret_cast<HCITD*>(evt.value.p);
TEST_ASSERT(itd);
return itd;
}
return NULL;
}
void IsochronousEp::enable() {
#if defined(TARGET_LPC1768)
LPC_USB->HcControl |= (OR_CONTROL_PLE | OR_CONTROL_IE);
#elif defined(TARGET_RZ_A1H)
uint32_t data;
data = ohciwrapp_reg_r(OHCI_REG_CONTROL) | OR_CONTROL_PLE | OR_CONTROL_IE;
ohciwrapp_reg_w(OHCI_REG_CONTROL, data);
#endif
}
void IsochronousEp::disconnect() {
m_pED->setSkip(); // skip bit on
ISO_DBG("rtos-queue: %d", m_itd_queue_count);
int queue_count = m_itd_queue_count;
Timer t;
t.reset();
t.start();
do {
HCITD* itd = get_queue_HCITD(10);
if (itd) {
ISO_DBG("delete ITD:%p from rtos-queue %d ms", itd, t.read_ms());
delete itd;
queue_count--;
t.reset();
}
} while(t.read_ms() < 50);
ISO_DBG("rtos-queue: %d, %d ms", queue_count, t.read_ms());
TEST_ASSERT(queue_count >= 0);
while(1) {
HCITD* itd = m_pED->dequeue<HCITD>();
if (itd == NULL) {
break;
}
ISO_DBG("delete ITD:%p from ED(%p)-queue", itd, m_pED);
delete itd;
TEST_ASSERT(queue_count > 0);
queue_count--;
}
TEST_ASSERT(queue_count == 0);
HCITD* tail = reinterpret_cast<HCITD*>(m_pED->TailTd);
ISO_DBG("delete ITD:%p from ED(%p)-tail", tail, m_pED);
TEST_ASSERT(tail);
delete tail;
m_pED->init_queue<HCITD>(NULL);
#if defined(TARGET_LPC1768)
_HCCA* hcca = reinterpret_cast<_HCCA*>(LPC_USB->HcHCCA);
#elif defined(TARGET_RZ_A1H)
_HCCA* hcca = reinterpret_cast<_HCCA*>(ohciwrapp_reg_r(OHCI_REG_HCCA));
#endif
TEST_ASSERT(hcca);
hcca->dequeue(m_pED);
ISO_DBG("delete ED:%p", m_pED);
delete m_pED;
m_pED = NULL;
}